Abstract: An engine starting device for controlling an engine start of a vehicle by driving a starter relay of the vehicle with a battery of the vehicle as a power supply has a control processing unit and a step-up circuit for stepping up the output of the battery and outputting a drive voltage for driving the control processing unit and the starter relay.

Abstract: In a startup operation of an internal combustion engine, the internal combustion engine is started by supplying fuel to only a first cylinder group formed of a portion of cylinders, from among a plurality of cylinders that make up the internal combustion engine, when a startup condition of the internal combustion engine has been satisfied, and then fuel starts to be supplied to a second cylinder group formed of the remaining cylinders after the internal combustion engine has started. Meanwhile, in a stopping operation of the internal combustion engine, the internal combustion engine is stopped when a shutoff condition of the internal combustion engine is satisfied, by first stopping the supply of fuel to the second cylinder group and then stopping the supply of fuel to the first cylinder group after the supply of fuel to the second cylinder group has been stopped.

Abstract: In a method for operating a starter device having a starter motor for starting an internal combustion engine, the starter motor is switched on and off via a starter controller having a switching relay when the starter motor is acted on by electrical power from an electrical energy store. The starter motor is controlled by the starter controller in a power-regulated manner during the starting operation.

Abstract: An engine start device includes a generator, a battery charged by the generator, a starter, an electric double layer capacitor and a DC/DC converter. The electric double layer capacitor is connected between the starter and the battery. The DC/DC converter has an input terminal connected to the battery and the electric double layer capacitor. The DC/DC converter has an output terminal connected to the starter and the electric double layer capacitor. According to voltage of the battery, internal DC resistance of the battery or internal DC resistance of the electric double layer capacitor, the DC/DC converter effects control of charge voltage of the electric double layer capacitor so as to stabilize voltage applied to a starter motor and stabilize the engine start.

Abstract: An engine starting control apparatus is basically provided with a motor control section, a valve timing control section and a start control section. The motor control section is configured to operate an electric motor to crank an engine with an output of the electric motor being adjustable. The valve timing control section is configured to operate a variable valve operating mechanism when the engine is started to change at least a close timing of an intake valve of the engine from an initial timing corresponding to a state in which the engine is stopped to a start timing for starting the engine. The start control section is configured to adjust the output of the electric motor as the close timing of the intake valve changes from the initial timing to the start timing.

Abstract: Methods and systems are provided for reducing variability in air-fuel control due to variations in brake booster vacuum levels at an engine start. A throttle position is adjusted during an engine start based on the vacuum availability in the brake booster to control a rate of intake aircharge flow. By allowing aircharge to enter the intake manifold at a more consistent rate, air-fuel control is improved and exhaust emissions are reduced.

Abstract: A method for improving starting of an engine that may be repeatedly stopped and started is presented. In one embodiment, the method disengages a starter in response to a first predicted combustion in a cylinder of the engine. The method may reduce one-way clutch degradation of a starter. Further, the method may reduce current consumption during engine starting.

Abstract: A starting system for outdoor power equipment that has a controller and a start button to control the activation of an internal combustion engine. The starting system includes a controller that receives a start signal from a start button. The controller monitors for the presence of an enable device in an enable device receptacle and, upon activation of the start button and the presence of the enable device in the enable device receptacle, the controller provides electric power to the electric load of the power equipment. When the start button is depressed for longer than a minimum engagement period, the controller initiates operation of the engine. If the start button is pressed for less than the minimum engagement period, the controller activates the electric load for an auxiliary period without starting the engine. During engine operation, if the start button is depressed, the controller terminates operation of the engine.

Abstract: An engine control device for a working vehicle in which a start switch starting an engine and a starter relay supplying electric current to a starting motor for assisting the starting of the engine in connection with the start switch are connected to a controller, the controller supplies the starter relay with electricity by the operation of the start switch, and drives the engine along with the driving of the starting motor, wherein the engine control device includes a check mechanism of the starting motor which stops the supply of electricity to the starter relay depending on an electricity supplying time of the starter relay.

Abstract: The starter has a system of pushing the pinion gear in the direction of the anti-motor side by using the attracting power of the electromagnetic switch via the shift lever. The switch coil of the electromagnetic switch is constituted of one coil that is electrically separated from the motor circuit. The mass of pinion gear is set to 100 g or less, the switch extrusion power stored in the drive spring is set to 70 N (Newton) or less, and the operation current of the electromagnetic switch is set to 12 amperes or less. With this starter, since the switch coil and the motor circuit can be electrically separated, the terminal for connection for connecting the conventional attracting coil and conventional “M terminal bolt” can be abolished. Further, by setting the operation current of the electromagnetic switch 10 to 12 amperes or less, it is possible to control the operation current directly by the ECU.

Abstract: A diesel engine start-up assisting device includes a plurality of first-and-second switching elements 11a to 11d between a common direct-current power source 1 and a plurality of electrical load 3a to 3d, a plurality of start-up assisting main parts 10a to 10d and an input-and-output unit 7. The diesel engine start-up assisting device is constructed so as to enable start-up of a diesel engine when power distribution is applied to at least one of the electrical loads 3a to 3d. In arrangement, the first-and-second switching elements 11a to 11d, the start-up assisting main parts 10a to 10d and the input-and-output unit 7 are integrated into one package having a lead frame. Defining the first-and-second switching element as a pair of switching elements, the first-and-second switching elements 11a to 11d are arranged in parallel with each other on the lead frame, and the lead frame has a notch part formed between two pairs of switching elements adjoined to each other.

Abstract: Methods and systems are provided for starting an engine in a vehicle. In one example, two or more energy storage devices are coupled in series to improve engine starting. The method and system may reduce engine starting time.

Abstract: The invention relates to a method for starting an internal combustion engine associated with a starter for driving the engine when starting the latter and to means for adapting the amount of injected fuel. According to the invention, the method comprises the following steps: during a first start operation, counting the number of revolutions (PMH) of the engine when it is driven by the starter; during a second starting operation following the first operation, adapting the amount (Q) of injected fuel based on the number of revolutions (PHM) counted during the first starting operation.

Abstract: A control apparatus includes a detection unit that detects a stop request to an engine, a throttle closing control unit that, when the stop request is detected, adjusts an opening amount of a throttle valve to an engine-stop throttle valve opening amount smaller than a current opening amount an engine stop detection unit that detects a stop of the engine, an engine-stop exhaust valve control unit that adjusts an opening/closing characteristic of an exhaust valve of a cylinder that will be placed initially in an intake stroke when the engine is restarted so that, when the opening amount of the throttle valve is adjusted to the engine-stop throttle valve opening amount and a stop of the engine is detected, the exhaust valve has an engine-stop exhaust valve opening/closing characteristic by which a closing timing of the exhaust valve is more delayed than a current closing timing of the exhaust valve.

Abstract: A method is disclosed for controlling engine output in a vehicle having a hydraulic power steering system. The method may include, during an idle condition where an engine speed is set to an idle speed, adjusting engine output based on a learned absolute steering wheel angle to compensate for changes in engine load caused by operation of the hydraulic power steering system. The learned absolute steering wheel angle may be based on a steering wheel angle relative to a steering wheel position at vehicle startup and operating conditions from previous vehicle operation before the vehicle startup.

Abstract: A remote engine start confirmation and vehicle monitoring and control system includes a transmitter and a controller capable of receiving and processing transmitter signals, the controller comprising a monitoring circuit for detecting a first pulsed voltage pattern and a second pulsed voltage pattern across the battery during an engine start procedure, a signaling circuit for signaling the disengagement of the starter from the engine after a detection of the termination of the first pulsed voltage pattern and the start of the second pulsed voltage pattern, and an initiation circuit for initiating the monitoring of a vehicle condition, such as overheating or low fuel, after the detection. A method for controlling the vehicle operation includes detecting an occurrence of a vehicle condition and performing an operation based on the detection, such as terminating ignition voltage or fuel supply or notifying the operator of the vehicle condition via the transmitter.

Abstract: A method and a system are provided for starting an engine that is employed for propulsion of a vehicle. The method includes determining that an engine start via a starter is desired, wherein the starter is powered by an energy storage device. The method also includes determining a state of charge of the energy storage device. The method additionally includes commanding the starter to crank the engine at a first predetermined speed, if the energy storage device is at or above a predetermined state of charge and supplying fuel to the engine for a first predetermined number of fueling events. Furthermore, the method includes commanding the starter to crank the engine at a second predetermined speed that is lower than the first predetermined speed and supplying fuel to the engine for a second predetermined number of fueling events, if the energy storage device is below the predetermined state of charge.

Abstract: In at least one embodiment, a system for controlling a vehicle climate control system in response to starting an engine with a remote start operation is provided. The system includes a first sensor for generating a cabin temperature signal indicative of a temperature within the vehicle. The system further includes a controller for controlling idle speed of the engine in response to the cabin temperature signal such that the controlled idle speed enables the climate control system to achieve a desired temperature.

Abstract: An automotive electrical system for a motor vehicle comprising an internal combustion engine, the automotive electrical system comprising a main electrical power source, a secondary electrical power source, safety critical electrical loads and non-safety critical electrical loads, and an electrical switching device arranged between the main and secondary electrical power sources and at least the safety critical electrical loads and configured to selectively connect at least the safety critical electrical loads to at least one of the main and secondary electrical power sources. The electrical switching device is configured to connect at least the safety critical electrical loads to the auxiliary electrical power source during the cranking of the internal combustion engine and/or when the motor vehicle is coasting with the internal combustion engine off and the main electrical power source is faulty.

Abstract: A method for engine starting is provided. The method may include performing idle-stop operation, and during a subsequent re-start, applying multi-strike ignition operation for a first combustion cycle. In this way, improved engine starting may be achieved with reduced emissions.

Abstract: A method for improving starting of an engine that may be repeatedly stopped and started is presented. In one embodiment, the method disengages a starter in response to a first predicted combustion in a cylinder of the engine. The method may reduce one-way clutch degradation of a starter. Further, the method may reduce current consumption during engine starting.

Abstract: An engine start control system for a vehicle includes a first switch with which a user operates to start the engine, a second switch, a third switch, a brake switch and an engine start control unit for controlling start of the engine. The engine start control unit provides a normal mode that allows to start the engine when the first switch is operated if the brake switch detects operation of the brake pedal and a failsafe mode that allows to start the engine when at least two of the first, second and third switches are operated even if the brake switch does not detect operation of the brake pedal.

Abstract: An idle reduction vehicle has a relay in a power supply line from a battery to a starter motor. The relay is driven between a contact-side state, in which contacts short-circuit, and a resistor-side state, in which the contacts are opened and a resistor is serially inserted into the power supply line. At an engine restart from idle reduction, an ECU drives the relay to the resistor-side state and starts energization to the motor, thereby suppressing an inrush current. The ECU detects a contact-side state fixation abnormality of the relay based on a battery voltage at the time when the ECU drives the relay to the resistor-side state and energizes the motor. The ECU detects a resistor-side state fixation abnormality of the relay based on the battery voltage at the time when the ECU drives the relay to the contact-side state and energizes the motor.

Abstract: The present invention provides a starter capable of keeping a state where a pinion and a ring gear maintain meshing with each other when an engine stops without providing a plunger stopper using a solenoid or the like. The state where the pinion and the ring gear maintain meshing with each other in the engine stop mode continues by movement resistance which occurs when a torque transmission member moves. Concretely, an inclination angle of a helical spline in a helical spline engagement part is set so that the above state continues. The helical spline engagement part is a part where a helical spline on the outer periphery of an output shaft of a starter motor and a helical spline on the inner periphery of the torque transmission member mesh with each. Consequently, the above state continues without a plunger stopper using a solenoid or the like.

Abstract: A control system for an engine including a starter may include a speed determination module that determines a first rotational speed of the engine during a run period contiguously following a period of starting the engine using the starter, and a speed control module that, when the first rotational speed falls below a predetermined speed greater than zero during the run period, selectively activates the starter to increase the first rotational speed. The speed control module may selectively activate the starter by selectively adjusting, based on the first rotational speed, a second rotational speed of a motor drive of the starter that supplies torque for cranking the engine and subsequently selectively engaging one of the motor drive and a first rotational member of the starter rotationally driven by the motor drive with a second rotational member of the engine. A related method is also provided.

Abstract: The starter has a system of pushing the pinion gear in the direction of the anti-motor side by using the attracting power of the electromagnetic switch via the shift lever. The switch coil of the electromagnetic switch is constituted of one coil that is electrically separated from the motor circuit. The mass of pinion gear is set to 100 g or less, the switch extrusion power stored in the drive spring is set to 70N (Newton) or less, and the operation current of the electromagnetic switch is set to 12 amperes or less. With this starter, since the switch coil and the motor circuit can be electrically separated, the terminal for connection for connecting the conventional attracting coil and conventional “M terminal bolt” can be abolished. Further, by setting the operation current of the electromagnetic switch 10 to 12 amperes or less, it is possible to control the operation current directly by the ECU.

Abstract: Startability of an internal combustion engine using a mixed fuel of gasoline and alcohol is improved. An intake passage of the engine has a main flow channel provided with a throttle valve and a bypass flow channel for bypassing the throttle valve. A bypass quantity adjusting mechanism adjusts the bypass quantity in the bypass flow channel. A control device detects or estimates the mixing ratio of alcohol of the fuel and controls the bypass quantity adjusting mechanism so that a bypass quantity before a first explosion is smaller than a bypass quantity after the first explosion when the mixing ratio of alcohol is equal to or more than a predetermined value.

Abstract: An engine control apparatus is provided that controls an engine which is restarted using an AC motor. The engine control apparatus comprises an engine rotational direction determining section, a restart command determining section and an engine restart prohibiting section. The engine rotational direction determining section is configured to determine a rotational direction of the engine. The restart command determining section is configured to determine if a restart command occurred while a rotational speed of the engine is decreasing due to an idle stop command. The engine restart prohibiting section is configured to selectively prohibit the engine from being restarted by the AC motor in response to the restart command upon determining the engine is rotating backward.

Abstract: An automatic starting device for the engine, which quietly and quickly restarts the engine when a re-acceleration request is made by a driver, is provided. In a case where it is judged that a vehicle is decelerating and fuel injection is currently stopped, when it is then judged that a brake pedal is released and an engine rpm is smaller than an engine rpm which allows recovery from a fuel-supply stop state, the controller disengages a lock-up clutch. Upon detection of reverse rotation of the engine based on a detection signal of the crank-angle sensor, the controller controls a pinion gear to be pushed out by a lever of a starter to be meshed with a ring gear. After the ring gear is rotated by a predetermined angle, the controller rotary-drives a motor of the starter to restart the engine.

Abstract: A vehicle has an engine, a starter motor, an energy storage system (ESS) for powering an auxiliary system, and a supercapacitor module for powering the starter motor during engine cranking and starting. The supercapacitor module disconnects from the starter motor to recharge. A DC-DC booster converter increases the level of voltage supplied from the ESS so as to charge the supercapacitor module to a relatively higher voltage level, such as approximately 125 to 140 percent of the voltage level supplied by the ESS. A method for preventing voltage sag in an auxiliary system of the vehicle includes disconnecting the supercapacitor module from the starter motor when the engine is running, and then charging the supercapacitor module using the ESS until a cranking support voltage equals a stored target voltage. A detected commanded cranking and starting of the engine causes the connection of the supercapacitor module to the starter motor.

Abstract: A method is provided for controlling a starting system for an engine of a motor vehicle. The motor vehicle includes a pre-spun starter for selective meshing with and starting of the engine, and a controller for controlling the starting of the engine. The method includes sensing of a rotational speed of the pre-spun starter, and sensing of a rotational speed of the engine. The method additionally includes regulating the rotational speed of the pre-spun starter to substantially synchronize the rotational speed of the pre-spun starter with the rotational speed of the engine. Furthermore, the method includes engaging the pre-spun starter gear with the engine, and applying torque by the pre-spun starter to the engine, such that the engine is started.

Abstract: A method for improving starting of an engine that may be repeatedly stopped and started is presented. In one embodiment, the method disengages a starter in response to a first predicted combustion in a cylinder of the engine. The method may reduce one-way clutch degradation of a starter. Further, the method may reduce current consumption during engine starting.

Abstract: A method for improving starting of an engine that may be repeatedly stopped and started is presented. In one embodiment, the method disengages a starter in response to a first predicted combustion in a cylinder of the engine. The method may reduce one-way clutch degradation of a starter. Further, the method may reduce current consumption during engine starting.

Abstract: A ring gear is connected to a crank shaft of an engine. A pinion is placed to face to the ring gear. When the engine is started, an ECU performs cranking of the engine under a state where the ring gear and the pinion are in mesh. The ECU releases the mesh state of the ring gear and the pinion after completion of the cranking of the engine. In particular, the ECU performs dispersion control to increase a degree of dispersion of a mesh portion of the ring gear which is meshed with the pinion when the rotation of the ring gear is stopped according to the engine stop. The dispersion control prevents the mesh portion of the ring gear and the mesh portion of the pinion from progressing abrasion and avoiding defect.

Abstract: The invention relates to a method of controlling the power supply to an electric starter that drives heat engine of a vehicle, in which the starter power supply is stopped after each supply phase for a first pre-determined period TOFF. According to the invention, the starter power supply is inhibited for a second pre-determined period TREP which is longer than the first period TOFF, when the number NON of consecutive starter supply phase ON1, ON2, ON3, ON4 exceeds a pre-determined value NMAX without the heat engine reaching an autorotation state.

Abstract: A starting system for outdoor power equipment that has a controller and a start button to control the activation of an internal combustion engine. The starting system includes a controller that receives a start signal from a start button. The controller monitors for the presence of an enable device in an enable device receptacle and, upon activation of the start button and the presence of the enable device in the enable device receptacle, the controller provides electric power to the electric load of the power equipment. When the start button is depressed for longer than a minimum engagement period, the controller initiates operation of the engine. If the start button is pressed for less than the minimum engagement period, the controller activates the electric load for an auxiliary period without starting the engine. During engine operation, if the start button is depressed, the controller terminates operation of the engine.

Abstract: A four stroke single cylinder combustion engine starting system with an electrical machine is operable as both a generator and a motor. The starting system has a single cylinder four stroke combustion engine. A piston of the engine is coupled to a shaft of the electrical machine. The starting system also has a motor driver having outputs coupled to the electrical machine. A controller is coupled to the driver and an ignition switch is coupled to the controller. In response to the controller receiving an ignition signal from the ignition switch, the driver controls the electrical machine to operate as a motor so that the electrical machine rotates in a reverse direction to move the piston in a reverse stroke cycle. After the piston reverses to a power stroke position of the reverse stroke cycle the driver controls electrical machine to rotate in a forward direction to move the piston in a forward stroke cycle to attempt to ignite the combustion engine.

Abstract: In a method for controlling an internal combustion engine (1) for a motor vehicle in stop-start operation, the internal combustion engine (1) is operated in the idling operating state. If there is a request for switch-off of the internal combustion engine (1) the torque produced by the internal combustion engine (1) is reduced while fuel continues to be injected. The fuel injection is switched off if the speed of the internal combustion engine (1) reaches a predetermined minimum value. The torque produced by the internal combustion engine (1) is increased again if the request for switching off the internal combustion engine (1) is canceled before the minimum speed is reached.

Abstract: A method of starting an engine is provided. A starter is initiated to impart a first engine speed to a crankshaft of the engine. Fuel injects at a first rate into at least one cylinder of the engine. Fuel in the at least one cylinder of the engine combusts to operate the engine at generally the first speed imparted to the crankshaft of the engine by the starter until a predetermined oil pressure develops within the engine.

Abstract: A combustion state detection device for an internal combustion engine includes: an ignition control unit that controls activation of a primary winding for ignition; a comparison value setting unit that sets a comparison value with respect to an ion signal; and a combustion state discrimination unit that determines the occurrence of misfire depending on the magnitude of the ion signal with respect to the comparison value; wherein the ignition control unit, after generating a spark, reactivates the primary winding at least one time during one combustion stroke so that an induction voltage similar to that generated in the secondary winding at around a time when the primary winding begins to be activated for the purpose of starting combustion is generated in the secondary winding.

Abstract: An engine starting method for starting an engine by causing first fuel injection when a crankshaft is reversely rotated by a predetermined angle at the start, and then rotating the crankshaft forward to perform first ignition, the method comprising the steps of immediately stopping driving of a starter motor when a starter switch is turned off before the first fuel injection at the start; and continuously driving the starter motor forward until a cylinder into which an air/fuel mixture is supplied by the first fuel injection performs at least one exhaust stroke and then stopping the driving of the starter motor when the starter switch is turned off after the first fuel injection at the start.

Abstract: A method controls an automatic shut-off process of an internal combustion engine having a start/stop device, when predetermined shut-off conditions are satisfied by corresponding influential variables, and controls a start-up process, when predetermined start-up conditions are satisfied by corresponding influential variables. Variables influencing the evaluation of the shut-off and/or start-up conditions include the presence of a vehicle key, the state of a tank ventilation system, the fuel tank fill level, the state of a diesel particulate filter, an activity state of a workshop mode, works mode, service mode and/or production mode, the current ambient temperature outside the vehicle, an evaluation of a device for detecting the occupancy, the detection of a cylinder synchronization process, an activity state of a driving speed control system, an auto hold function in vehicles with automatic transmissions, an electric parking brake, and/or a hill hold function.

Abstract: A vehicle control system is programmed to stop the vehicle's internal combustion engine upon certain conditions including the vehicle being stopped and engine temperature having reached a minimum operating level. On vehicles equipped with air brakes and having an engine driven air compressor, engine restarts are provided by an air pressure supported hydraulic motor once triggered by operator actions such as releasing the brake and/or depressing the vehicle's accelerator indicative of the driver's intention to move the vehicle.

Abstract: The vehicle-use power supply control apparatus includes a first battery supplying electric power to a load, an alternator driven by a vehicle engine, a second electric accumulator parallel-connected to the first battery, an electric power converter performing two-way power transmission between the first and second batteries, and a power supply control unit. The power supply control includes a function of setting a target power generation efficiency index, a function of setting a target power generation amount of the alternator on the basis of the target power generation efficiency index, while referring to a map defining relationship between a power generation efficiency index and a power generation amount of the alternator, and a function of controlling an amount and a transmission direction of transmission power of the electric power converter in order that an amount of electric power generated by the alternator becomes equal to the target power generation amount.

Abstract: An eco-run control device sends an engine stop request to an engine control device when predetermined stop requirements are satisfied, causes the engine control device to perform an engine stop control operation, and drives a starter to restart the engine when predetermined restart requirements are satisfied during the engine stop control operation. This eco-run control device includes: a detecting unit that detects a starting operation to start the engine; and a control unit that causes the starter to restart the engine, if the starting operation is detected during the engine stop control operation and the engine speed is lower than a predetermined speed.

Abstract: An eco-run control device is mounted on a vehicle and is capable of performing eco-run control to stop an engine when predetermined stop requirements are satisfied and restart the engine when predetermined start requirements are satisfied later. This eco-run control device includes: a monitoring unit that monitors the state of an ignition; a communicating unit that communicates with a plurality of control devices that receive power supplies from a power supply line that is connected to a power source via the ignition; and an initialization controlling unit that initializes the data with respect to the eco-run control stored in a memory, when the monitoring unit determines that the ignition is in an OFF state, and that the communications with two or more of the control devices are interrupted.

Abstract: An engine for use in an air hybrid vehicle comprises at least one cylinder having a piston (20) defining a variable volume working chamber (10) and intake (12, 14) and exhaust (16) valves controlling the flow of air into and out of the working chamber. The cylinder is operable in any one of at least two modes, namely a first mode in which power is generated by burning fuel in the working chamber (10), and a second mode in which the cylinder acts to compress air drawn into the working chamber (10) and to store the compressed air in an air tank (36). The engine further comprises a non-return valve (32) in an intake port leading to an intake valve (12) of the cylinder so as to define an auxiliary chamber (30) in the intake port between the intake valve (12) and the non-return valve (32). A passage (24) connecting the auxiliary chamber (30) to the air tank (36) contains a valve (34) for controlling the flow of compressed air between the auxiliary chamber (30) and the air tank (36).

Abstract: A first ignition cylinder that performs ignition first is set based on an engine stop position in automatic start. Existence/nonexistence of a misfire in the first ignition cylinder is determined based on whether a difference ?Ne between engine rotation speed at a predetermined crank angle in an interval from timing immediately before the ignition to timing immediately after the ignition of the first ignition cylinder (e.g., at TDC of first ignition cylinder) and engine rotation speed at a predetermined crank angle before ignition of a second ignition cylinder (e.g., at TDC of second ignition cylinder) is equal to or smaller than a predetermined misfire determination threshold value Nef. When misfire time number of the first ignition cylinder exceeds a predetermined value, fuel supply to the first ignition cylinder is prohibited and the automatic start is started from the second ignition cylinder.

Abstract: In a power supply device of the invention, when the state of charge SOC1 of a low-voltage battery is lower than a discharging reference value Shi1 below a full charge level and when the state of charge SOC2 of a high-voltage battery is not lower than a discharging reference value Slow2 at a system-off time, the low-voltage battery is charged close to its full charge level with the electric power supplied from the high-voltage battery. The lead acid battery used for the low-voltage battery has the high potential for deterioration in the continuously low state of charge SOC. The lithium secondary battery used for the high-voltage battery has the high potential for deterioration in the continuously high state of charge SOC. The charge of the low-voltage battery in combination with the discharge of the high-voltage battery enables both the low-voltage battery and the high-voltage battery to have respective favorable states of charge with little potentials for deterioration.

Abstract: In an engine starting system, when a first solenoid is energized at a first timing in response to any one of a turning on of a starter switch and an occurrence of an engine restart request, a solenoid actuator shifts a pinion to a ring gear to be engaged with the ring gear. When a second solenoid is energized, a solenoid switch member energizes a motor. A determiner determines a second timing of energization of the second solenoid after the first timing so that a first delay time from the first timing to the second timing when the first timing is responsive to the turning on of the starter switch is different from a second delay time from the first timing to the second timing when the first timing is responsive to the occurrence of the engine restart request.